Elementary education majors experience hands-on learning in introductory biology

Faculty members from the University of South Dakota attended the Curriculum Reform Institute offered by the University of Wisconsin at Oshkosh, WI, during the summer of 2002 to design a course sequence for elementary education majors that better meets their needs for both content and pedagogy based on the science education standards. The special section of introductory biology that resulted from this workshop is designed to use laboratories and activities that either help students learn major concepts in the life sciences or model how to teach these concepts to their future K-8 students. This study describes how the active, hands-on learning opportunity for preservice teachers with its emphasis on both content and performance-based assessment was implemented in an introductory biology course for elementary education majors during the spring of 2004. During the initial offering of this course, student perceptions about what helped them to learn in the special section was compared with their nonscience major peers in the large lecture-intensive class that they would have taken. Each group of students completed early and late web-based surveys to assess their perceptions about learning during the courses. After the completion of the course, students in the special section appreciated how the relevance of science and conducting their own scientific experimentation helped them learn, enjoyed working and studying in small groups, valued diverse class time with very little lecture, were more confident in their abilities in science, and were more interested in discussing science with others. This course format is recommended for science classes for preservice teachers.     

Preservice elementary teachers’ willingness to specialize in science and views on evolution

Background

Acceptance and understanding of evolutionary ideas remains low in the United States despite renewed science education standards, nearly unanimous acceptance among scientists, and decades of research on the teaching and learning of evolution. Early exposure to evolutionary concepts may be one way to reduce resistance to learning and accepting evolution. While there is emerging evidence that elementary students can learn and retain evolutionary ideas, there is also emerging evidence that elementary teachers may be unprepared to teach evolution. It may not be possible to train elementary teachers like their secondary counterparts who receive specialized training in science. This exploratory study was designed to determine if the 147 surveyed preservice elementary teachers (PETs) who are most willing to specialize in science maintain a greater understanding and acceptance of evolution. Such a relationship could have implications for teacher training and science instruction at elementary schools.

Results

As willingness to specialize in science increases so too does acceptance of evolution. For both measures, there was a monotonic increase with increasing willingness to specialize in science. There was a significant correlation (p?=?.047) between willingness to specialize in science and acceptance of evolution as measured by the MATE. There was not a significant correlation between willingness to specialize in science and understanding of evolution as measured by the CINS (p?=?.21). The thirty-two PETs who are enthusiastically willing to specialize in science had the highest understanding and acceptance of evolution.

Conclusions

It may be possible to identify prospective elementary teachers that could assume roles as specialists simply by identifying PETs’ willingness to specialize. Such students appear to enter elementary teacher preparation programs with the science background and enthusiasm for science required to be specialists without the need for much additional training. Thus, science teacher educators could help local elementary school principals identify graduating, and recently graduated, elementary teachers who are willing to specialize in science. Identified teachers could serve as specialists to work with their building and district colleagues to develop, among other topics, evolution related curricular materials and facilitate the implementation of those materials through co-teaching and peer coaching.

     

Teacher candidates in the garden

Recent science education reform has led to an increased emphasis on engaging students in inquiry and science practices rather than having them simply memorize scientific facts. However, many teachers of elementary science may themselves have had more traditional science learning experiences, and may therefore be unsure about inquiry-based teaching methods. One way to enhance preservice teachers' comfort with and desire to teach science using a hands-on approach might be to engage them in science learning experiences alongside children during their educator preparation program. The purpose of this article is to share how one faculty member and a cooperating teacher from a partner school involve teacher candidates in working with children in the school's garden, allowing them to personally experience inquiry while witnessing firsthand the potential benefits to children of authentic science learning through garden based activities.     

Preservice Teacher Understanding and Vision of how to Teach Biological Evolution

The learning and teaching of biological evolution is conceptually challenging. To fully comprehend evolution, it is posited that individuals also need to understand the roles that the nature of science and situations of chance play in the process. The consistent detection of misconceptions of evolution suggests that new approaches to increasing understanding need to be explored. I predicted that preservice teachers’ ideas for teaching biological evolution could be influenced by three brief web-based interventions, one focused on the common misconceptions of evolution, one on the nature of science, and one on situations of uncertainty in the context of evolution. An experimental group received a combination of the three web-based tutorials while a control group received the misconceptions and nature of science instruction and a time on task filler tutorial. Participants were directed to develop a lesson idea applying the knowledge they learned from the tutorials. The lesson ideas were examined for evidence of the influence of the web-based instruction, participant understanding and misconceptions of concepts, and their ideas about teaching evolution. The results of this study revealed that the participating preservice teachers held a wide range of conception and misconception of evolution, were somewhat influenced by the tutorials, and had an array of visions for teaching evolution. The outcomes support the need for further investigation into the multifaceted nature of preparing preservice teachers to teach evolution.     

Experiments with Light

This article describes an unlikely collaboration between a high school chemistry teacher and a high school English teacher who attempted to teach scientific concepts through poetry. Inspired by poet John Updike's (1960) "Cosmic Gall," these two teachers crafted writing tasks aimed at teaching science content through literary devices. The result was an inspiring account and unlikely marriage of academic disciplines.     

Getting the Message Over—An Examination of the Teaching of the Genetic Code

Teachers are required to introduce a number of new curriculum initiatives: technological awareness, economic awareness, process science, industry education—and all whilst trying to teach some biology. This article describes a way in which a number of these areas can be delivered starting from a biological base. The project was developed by a team of biology teachers, HE teachers, and technology and health advisers.     

Evolutionary Medicine: A Key to Introducing Evolution

Science teachers can use examples and concepts from evolutionary medicine to teach the three concepts central to evolution: common descent, the processes or mechanisms of evolution, and the patterns produced by descent with modification. To integrate medicine into common ancestry, consider how the evolutionary past of our (or any) species affects disease susceptibility. That humans are bipedal has produced substantial changes in our musculoskeletal system, as well as causing problems for childbirth. Mechanisms such as natural selection are well exemplified in evolutionary medicine, as both disease-causing organism and their targets adapt to one another. Teachers often use examples such as antibiotic resistance to teach natural selection: it takes little alteration of the lesson plan to make explicit that evolution is key to understanding the principles involved. Finally, the pattern of evolution can be illustrated through evolutionary medicine because organisms sharing closer ancestry also share greater susceptibility to the same disease-causing organisms. Teaching evolution using examples from evolutionary medicine can make evolution more interesting and relevant to students, and quite probably, more acceptable as a valid science.     

Using Inquiry to Learn about Soil: A Fourth Grade Experience

In this article, we describe a fourth-grade inquiry unit on soil. The unit was designed and taught by preservice elementary teachers as part of a university science methods course. Using a student-driven inquiry approach to designing curriculum, the unit engaged fourth graders in learning about the physical properties soil, erosion, worms, and plants. Hands-on activities, literacy strategies, and informational texts and websites were used to build student learning.     

Patterns of Change: Forces and Motion

Patterns of Change: Forces and Motion is an integrated science lesson that uses the 5E lesson cycle to tie together science with language arts, mathematics, literature, technology, engineering and social studies in an engaging format applicable for young learners. This lesson has been uniquely designed for the purpose of providing elementary teachers with ideas for using hands-on minds-on activities to foster inquiry and discussion, while engaging their students to use technology as a learning tool. This lesson has been used on the elementary level to teach students about the forces that have an effect on motion.     

Teaching Density with a Little Drama

This article provides an example of an innovative science activity applied in a science methods course for future elementary teachers at a small university in northeastern Turkey. The aim of the activity is to help prospective elementary teachers understand the density concept in a simple way and see an innovative teaching example.     

Windmills by design: Purposeful curriculum design to meet next generation science standards in a 9–12 physics classroom

The Next Generation Science Standards (NGSS) challenges science teachers to think beyond specific content standards when considering how to design and implement curriculum. This lesson, “Windmills by Design,” is an insightful lesson in how science teachers can create and implement a cross-cutting lesson to teach the concepts of force, motion, and Bernoulli's principle. This 9–12 lesson requires students to consider the science behind windmill design by engineering windmill blades that can produce the most power in a class competition. The lesson is designed as a 5E lesson incorporating essential features of inquiry-based instruction.     

Prospective elementary science teachers’ understanding of photosynthesis and cellular respiration in the context of multiple biological levels as nested systems

In this study, Turkish prospective elementary science teachers’ understanding of photosynthesis and cellular respiration has been analysed within the contexts of ecosystem knowledge, organism knowledge and interconnection knowledge (IK). In the analysis, concept maps developed by 74 prospective teachers were used. The study was carried out with prospective teachers in their final year who were enrolled in the special teaching methods course. The results show that prospective teachers’ understanding of photosynthesis, cellular respiration, energy flow and matter cycling is quite different from one another’s. In addition, the present study revealed that prospective elementary science teachers showed weak understanding of energy flow and matter, cycling and cellular respiration concepts and IK category but they had strong understanding of photosynthesis concept. Prospective teachers also experience difficulties in understanding connections between macro- and microbiological systems. The study concludes with suggestions for more meaningful biology education.     

Exploring continuity equation via a modeling activity: in the context of crowd science

Abstract

Using problems from real life contexts which is related to learners’ environment or their culture plays an important role in their learning that concept. In this regard, science educators especially physics educators search for real-life domain of theoretical concepts for effective science teaching and they consider analogical and physical models as an opportunity in their instruction. In the presented activity, we worked with 66 senior pre-service science teachers from our science teaching methods course. We used crowd movements as a real-life domain of our analogical models to scientifically explain a stampede case, then utilized physical model to explore continuity equation. Real life problem based scenarios could be used while taking advantage of the 3?D modeling in teaching of scientific principle. As a result, we found that pre-service teachers were able to make scientific explanation for causes of stampedes by using modeling activity. High school teachers and upper-level instructors could benefit from including the modeling activity introduced in this study to help their students understand the concepts related to continuity equation by designing a physical model based on an analogical model. Via the physical model, students are able to make predictions, observations, interpretations and explanations of a complex and abstract scientific phenomenon.     

The pH ruler: a Java applet for developing interactive exercises on acids and bases

In introductory biochemistry courses, it is often a struggle to teach the basic concepts of acid-base chemistry in a manner that is relevant to biological systems. To help students gain a more intuitive and visual understanding of abstract acid-base concepts, a simple graphical construct called the pH ruler Java applet was developed. The applet allows students to visualize the abundance of different protonation states of diprotic and triprotic amino acids at different pH values. Using the applet, the student can drag a widget on a slider bar to change the pH and observe in real time changes in the abundance of different ionization states of this amino acid. This tool provides a means for developing more complex inquiry-based, active-learning exercises to teach more advanced topics of biochemistry, such as protein purification, protein structure and enzyme mechanism.     

Pre-service Teachers and Stress During Microteaching: An Experimental Investigation of the Effectiveness of Relaxation Training with Biofeedback on Psychological and Physiological Indices of Stress

Pre-service teacher stress is an understudied research area, with the majority of research focusing on subjective reports of stress. The present study sought to examine the influence of stress-reduction techniques on both subjective and objective indicators of stress during microteaching in preservice teachers. A sample of 44 preservice teachers were randomly assigned to one of three intervention groups; biofeedback, relaxation, or control. Participants in the biofeedback group received relaxation-assisted biofeedback training designed to teach participants the physiological signs of the stress response using HeartMath monitor, along with the HeartMath Quick Coherence® technique. Those in the relaxation group were given training in the HeartMath Quick Coherence relaxation technique, with no biofeedback training. Finally, those in the control group did not receive any relaxation or biofeedback training. Using a repeated-measures design, both psychological and physiological indices of stress were measured before and after students engaged in microteaching approaches. Examination of the psychological ratings identified that feelings of calm increased across time; this showed that participants were more comfortable with the microteaching situation with repeated practice. However, none of the physiological interventions were effective in reducing stress. The present study highlights practice as a useful strategy to reduce stress in microteaching situations and points to the importance of employing evidence-based interventions when attempting to reduce stress.     

Biosafety, biodiversity and significance of Microbial Resource Centers (MRCs) in microbiology education

Summary Interest in the intrinsic behavior of microorganisms has led to the establishment of centers of expertise, known as Microbial Resource Centers (MRCs) built around specialized collections of cultures of microorganisms. Their main function is to accession, preserve and distribute authenticated, viable samples of microorganisms in consultation with the international scientific community for study and application. Microorganisms, which are exceptionally diverse, are found almost everywhere and affect human society in countless ways. Thus, modern microbiology has a great impact on medicine, agriculture, food science, ecology, genetics, biochemistry and many other fields. MRCs appear to be equally important to industry, to academia, and from the elementary to high school science teachers who can order specific educational strains. The basic microbiological knowledge of human society possesses the potential to revolutionize many aspects of human life. MRCs are a key resource to underpin these developments.     

Community arts: (Re)contextualizing the narrative of teaching and learning

ABSTRACT

Education in the United States is often characterized by testing and standardized outcomes, and bears little relevance to the culture and the community that surrounds both students and teachers. Conversely, community arts connect the philosophies of art and education to the larger spheres of culture and community. The community thus becomes an educational space in which both the teachers and students are motivated to learn from each other through a reciprocal relationship that changes the dynamic of both teaching and learning. Consequently, the (re)contextualization of art and education within culture and community has distinct policy implications regarding both what we teach and the way we teach it. There is an opportunity to increase the significance of art education in a democratic society if we embrace practices that empower preservice teachers to analyze how artmaking practices shape their own sensibilities and those of the communities in which they live. This article suggests a field experience model for informing cross-cultural understandings of community-based pedagogy, participation, and collaboration that challenges existing educational policy while informing the values and beliefs of the preservice teacher. It presents the opportunity to develop socially relevant programs for use in the teaching of art that include community, social justice, democracy, collective responsibility, activism, and equity—among others—that confront established perceptions of both art and education.     

《动物生物学》教学对生命科学发展和人才培养的作用

动物生物学是揭示动物生命活动规律的科学。作为生命科学专业本科学生最早接触到的主干课程之一,动物生物学的教学对于学生了解生物学的基本概念和基础知识、构建生命科学的知识体系和思维方式、培养和巩固专业兴趣十分重要。系统回顾和总结了动物生物学研究对生命学科发展的贡献,阐明了动物生物学教学对生命科学人才培养与学科建设的作用,引起广大的生物学教学工作者和管理者对动物生物学教学的重视,促进传统重要基础课程的建设与发展。     

Metrology in physics,chemistry, and biology

The association of physics and chemistry with metrology (the science of measurements) is well documented. For practical purposes, basic metrological measurements in physics are governed by two components, namely, the measure (i.e., the unit of measurement) and the measurand (i.e., the entity measured), which fully account for the integrity of a measurement process. In simple words, in the case of measuring the length of a room (the measurand), the SI unit meter (the measure) provides a direct answer sustained by metrological concepts. Metrology in chemistry, as observed through physical chemistry (measures used to express molar relationships, volume, pressure, temperature, surface tension, among others) follows the same principles of metrology as in physics. The same basis percolates to classical analytical chemistry (gravimetry for preparing high-purity standards, related definitive analytical techniques, among others). However, certain transition takes place in extending the metrological principles to chemical measurements in complex chemical matrices (e.g., food samples), as it adds a third component, namely, indirect measurements (e.g., AAS determination of Zn in foods). This is a practice frequently used in field assays, and calls for additional steps to account for traceability of such chemical measurements for safeguarding reliability concerns. Hence, the assessment that chemical metrology is still evolving.     

Beyond the Movie Screen: An Antarctic Adventure

Movies depicting science-related issues often capture the attention of today's youth. As an instructional tool, movies can take us beyond the drama and action and thrilling scenes. In this article we share our experiences of using the movie Eight Below as a centerpiece for developing high school students’ understanding of basic chemistry concepts. In addition to the science concepts developed using the context of the movie, we engaged students in thinking about the ethical dilemmas embedded in the movie.